POJ-1785-Binary Search Heap Construction(笛卡尔树)
Description
Read the statement of problem G for the definitions concerning trees. In the following we define the basic terminology of heaps. A heap is a tree whose internal nodes have each assigned a priority (a number) such that the priority of each internal node is less
than the priority of its parent. As a consequence, the root has the greatest priority in the tree, which is one of the reasons why heaps can be used for the implementation of priority queues and for sorting.
A binary tree in which each internal node has both a label and a priority, and which is both a binary search tree with respect to the labels and a heap with respect to the priorities, is called a treap. Your task is, given a set of label-priority-pairs, with unique labels and unique priorities, to construct a treap containing this data.
A binary tree in which each internal node has both a label and a priority, and which is both a binary search tree with respect to the labels and a heap with respect to the priorities, is called a treap. Your task is, given a set of label-priority-pairs, with unique labels and unique priorities, to construct a treap containing this data.
Input
The input contains several test cases. Every test case starts with an integer n. You may assume that 1<=n<=50000. Then follow n pairs of strings and numbers l1/p1,...,ln/pn denoting the label and priority of each node. The strings are non-empty and composed
of lower-case letters, and the numbers are non-negative integers. The last test case is followed by a zero.
Output
For each test case output on a single line a treap that contains the specified nodes. A treap is printed as (< left sub-treap >< label >/< priority >< right sub-treap >). The sub-treaps are printed recursively, and omitted if leafs.
Sample Input
7 a/7 b/6 c/5 d/4 e/3 f/2 g/1 7 a/1 b/2 c/3 d/4 e/5 f/6 g/7 7 a/3 b/6 c/4 d/7 e/2 f/5 g/1 0
Sample Output
(a/7(b/6(c/5(d/4(e/3(f/2(g/1))))))) (((((((a/1)b/2)c/3)d/4)e/5)f/6)g/7) (((a/3)b/6(c/4))d/7((e/2)f/5(g/1)))
Source
思路:先按字符串排下序,建笛卡尔树,递归输出。
#include <cstdio> #include <cstring> #include <algorithm> using namespace std; struct S{ int id,val; int parent,l,r; }node[50005]; int stk[50005],top; char s[50005][20]; bool cmp(struct S a,struct S b) { if(strcmp(s[a.id],s[b.id])<0) return 1; return 0; } int build(int n) { int i; top=0; stk[top]=0; for(i=1;i<n;i++) { while(top>=0 && node[stk[top]].val<node[i].val) top--;//注意。这里让小于当前值的出栈 if(top>-1) { node[i].parent=stk[top]; node[node[stk[top]].r].parent=i; node[i].l=node[stk[top]].r; node[stk[top]].r=i; } else { node[stk[0]].parent=i; node[i].l=stk[0]; } stk[++top]=i; } return stk[0];//返回根节点 } void dfs(int x) { printf("(");//先输出左括号 if(node[x].l!=-1) dfs(node[x].l);//假设有左子树。就先输出左子树 printf("%s/%d",s[node[x].id],node[x].val);//输出自己 if(node[x].r!=-1) dfs(node[x].r);//再输出右子树 printf(")");//右括号 } int main() { int n,i,root; while(~scanf("%d",&n) && n) { for(i=0;i<n;i++) { scanf("%*[ ]%[a-z]/%d",s[i],&node[i].val); node[i].id=i; node[i].parent=node[i].l=node[i].r=-1; } sort(node,node+n,cmp);//按字符串字典序排序 root=build(n);//建树 dfs(root);//递归输出 printf("\n"); } }